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#include <stdint.h>
#include <csignal>
#include <cmath>
#include <iostream>
#include <iomanip>
#include <sstream>
#include <algorithm>
#include <vector>

using namespace std;


typedef unsigned int uint;

#define self (*this)


class DecBigInt {
public:
  typedef uint32_t uint1d_t; // digit type
  typedef int32_t  int1d_t;  // signed digit type
  typedef uint64_t uint2d_t; // double-digit type
  typedef int64_t  int2d_t;  // signed double-digit type
  
private:
  std::vector<uint1d_t> v; // digits
  bool n;                  // sign (true if negative)
  
public:
  static uint1d_t const RADIX = 1000000000;        // digits system base
  static uint     const RADIX_DEC_DIGITS = 9;      // decimal digits per actual digit
  static uint     const RADIX_BITS = 30;           // bits per actual digit
  static uint     const MIN_KARTASUBA_DIGITS = 32; // empirical result
  
  // constructors/destructor
  DecBigInt() { clear(); }
  template<typename some_t> DecBigInt(some_t a) { self = a; }
  ~DecBigInt() { }
  
  // clear
  DecBigInt & clear() { v.clear(); n = false; return self; }
  
  // integer assignment
  #define UINT_ASSIGN(uint_t) \
    DecBigInt & operator=(uint_t const &a) { \
      clear(); for(uint_t t = a; t; t /= RADIX) v.push_back(t % RADIX); return self; \
    }
  #define INT_ASSIGN(int_t) \
    DecBigInt & operator=(int_t const &a) { \
      if(a < 0) { return (self = -a).neg(); } \
      clear(); for(int_t t = a; t; t /= RADIX) v.push_back(t % RADIX); return self; \
    }
  UINT_ASSIGN(uint1d_t);
  UINT_ASSIGN(uint2d_t);
  INT_ASSIGN(int1d_t);
  INT_ASSIGN(int2d_t);
  #undef UINT_ASSIGN
  #undef INT_ASSIGN
  
  // string assignment
  DecBigInt & operator=(std::string const &a) { std::istringstream ss(a); ss >> self; return self; }
  DecBigInt & operator=(char const * const &a) { return (self = std::string(a)); }
  
  // floating-point value assignment
  #define NUM_ASSIGN(num_t) \
    DecBigInt & operator=(num_t const &a) { \
      clear(); \
      num_t r = floor(fabs(a)); \
      while(r > 0.5) { \
        v.push_back((fmod(r, RADIX))); \
        r = floor(r / RADIX); \
      } \
      n = (a < 0); \
      return self; \
    }
  NUM_ASSIGN(float)
  NUM_ASSIGN(double)
  NUM_ASSIGN(long double)
  #undef NUM_ASSIGN
  
  // copying
  DecBigInt & operator=(DecBigInt const &a) { v = a.v; n = a.n; return self; }
  
  // swap
  DecBigInt & swap(DecBigInt &a) { std::swap(n, a.n); v.swap(a.v); return self; }
  
  // toggle sign
  DecBigInt & neg() { n = not n; return self; }
  
  // absolute value
  DecBigInt abs() const { DecBigInt ret(self); ret.n = false; return ret; }
  
  // unary + and - (note: unary + is useful for making a copy)
  DecBigInt operator+() const { return self; }
  DecBigInt operator-() const { DecBigInt ret(self); ret.neg(); return ret; }
  
  // digits count
  uint digits() const { return v.size(); }
  
  // signum
  int sgn_nz() const { return 1 - 2 * n; } // non-zero version
  int sgn() const { return (self ? sgn_nz() : 0); }
  
  // cast to bool (true iff non-zero)
  operator bool() const { return not v.empty(); }
  
  // cast to integer or floating-point types
  #define ARITHMETIC_CAST(some_t) \
    operator some_t() const { \
      some_t ret = 0; \
      for(uint i = digits(); i--;) ret = ret * RADIX + v[i]; \
      return (n ? -ret : ret); \
    }
  ARITHMETIC_CAST(uint1d_t);
  ARITHMETIC_CAST(int1d_t);
  ARITHMETIC_CAST(uint2d_t);
  ARITHMETIC_CAST(int2d_t);
  ARITHMETIC_CAST(float);
  ARITHMETIC_CAST(double);
  ARITHMETIC_CAST(long double);
  #undef ARITHMETIC_CAST
  
  // cast to string
  operator std::string() const { std::ostringstream ss; ss << self; return ss.str(); }
  
  // pop leading zeros
  DecBigInt & fix() { while(self and (v.back() == 0)) v.pop_back(); if(not self) n = false; return self; }
  
  // compare absolute values (positive: greater, 0: equal, negative: lower)
  int cmp_abs(DecBigInt const &a) const {
    int sd = digits(), ad = a.digits();
    if(sd != ad) return sd - ad;
    for(uint i = sd; i--;) if(v[i] != a.v[i]) return (v[i] > a.v[i] ? 1 : -1);
    return 0;
  }
  
  // compare DecBigInts
  int cmp(DecBigInt const &a) const {
    if(n == a.n) return sgn_nz() * cmp_abs(a);
    /* else */   return a.n - n;
  }
  
  // compare absulute value against small unsigned number
  int cmp_abs(uint1d_t const &a) const {
    if(not self)     return (a ? -1 : 0);
    if(digits() > 2) return true;
    uint2d_t sv = self;
    return (sv == a ? 0 : (sv > a ? 1 : -1));
  }
  
  // compare against small unsigned number
  int cmp(uint1d_t const &a) const {
    if(self.n) return -1;
    /* else */ return cmp_abs(a);
  }
  
  // compare against small signed number
  int cmp(int1d_t const &a) const {
    if(a >= 0) return (n ? -1 : cmp(uint1d_t(a)));
    /* else */ return (n ? -cmp_abs(uint1d_t(-a)) : 1);
  }
  
  // comparison operators
  template<typename some_t> bool operator< (some_t rhs) const { return cmp(rhs) <  0; }
  template<typename some_t> bool operator<=(some_t rhs) const { return cmp(rhs) <= 0; }
  template<typename some_t> bool operator==(some_t rhs) const { return cmp(rhs) == 0; }
  template<typename some_t> bool operator!=(some_t rhs) const { return cmp(rhs) != 0; }
  template<typename some_t> bool operator>=(some_t rhs) const { return cmp(rhs) >= 0; }
  template<typename some_t> bool operator> (some_t rhs) const { return cmp(rhs) >  0; }
  
  // increment absolute value
  DecBigInt & inc_abs() {
    uint i = 0, sd = digits();
    for(; i < sd; ++i) if(++v[i] == RADIX) v[i] = 0; else break;
    if(i == sd) v.push_back(1);
    return self;
  }
  
  // decrement absolute value
  DecBigInt & dec_abs() {
    if(not self) { v.push_back(1); return neg(); }
    // assertion: some digit is non-zero for each non-zero number
    for(uint i = 0; true; i++) if(--v[i] >= RADIX) v[i] = RADIX - 1; else break;
    return fix();
  }
  
  // incrementation/decrementation operators
  DecBigInt & operator++() { return (n ? dec_abs() : inc_abs()); }
  DecBigInt & operator--() { return (n ? inc_abs() : dec_abs()); }
  DecBigInt operator++(int) { DecBigInt ret(self); ++self; return ret; }
  DecBigInt operator--(int) { DecBigInt ret(self); --self; return ret; }
  
  // fix single digit
  static uint1d_t digit_fix(uint1d_t const &a) {
    if(a < RADIX)                 return a;
    /* else */ if(int1d_t(a) > 0) return a - RADIX;
    /* else */                    return a + RADIX;
  }
  
  // add absolute values
  DecBigInt & add_abs(DecBigInt const &a) {
    uint1d_t t = 0;
    uint sd = digits(), ad = a.digits();
    if(sd < ad) { v.resize(ad, 0); sd = ad; }
    uint i = 0;
    for(; i < ad; ++i) v[i] = digit_fix(t = (t >= RADIX) + v[i] + a.v[i]);
    for(; i < sd; ++i) v[i] = digit_fix(t = (t >= RADIX) + v[i]);
    if(t >= RADIX) v.push_back(1);
    return self;
  }
  
  // subtract absolute values
  DecBigInt & sub_abs(DecBigInt const &a) {
    int1d_t t = 0;
    uint sd = digits(), ad = a.digits();
    uint i = 0;
    for(; i < ad; ++i) v[i] = digit_fix(t = -(t < 0) + v[i] - a.v[i]);
    for(; i < sd; ++i) v[i] = digit_fix(t = -(t < 0) + v[i]);
    return fix();
  }
  
  // reverse (minuend-based) subtract absolute values
  DecBigInt & min_abs(DecBigInt const &a) {
    int1d_t t = 0;
    uint sd = digits(), ad = a.digits();
    if(sd < ad) { v.resize(ad, 0); sd = ad; }
    for(uint i = 0; i < sd; ++i) v[i] = digit_fix(t = -(t < 0) - v[i] + a.v[i]);
    return fix();
  }
  
  // addition
  DecBigInt & operator+=(DecBigInt const &rhs) {
    if(n == rhs.n)       return add_abs(rhs);
    int c = cmp_abs(rhs);
    if(c == 0)           return clear();
    else if(c > 0)       return sub_abs(rhs);
    else /* if(c < 0) */ return min_abs(rhs).neg();
  }
  
  // subtraction
  DecBigInt & operator-=(DecBigInt const &rhs) {
    if(n != rhs.n)       return add_abs(rhs);
    int c = cmp_abs(rhs);
    if(c == 0)           return clear();
    else if(c > 0)       return sub_abs(rhs);
    else /* if(c < 0) */ return min_abs(rhs).neg();
  }
  
  // addition and subtraction operators
  DecBigInt operator+(DecBigInt const &rhs) const { return ((+self) += rhs); }
  DecBigInt operator-(DecBigInt const &rhs) const { return ((+self) -= rhs); }
  
  // multi-digit right keep
  DecBigInt & rdkeep(int const &ds) {
    if(uint(ds) >= digits()) return self;
    v.erase(v.begin() + ds, v.end());
    return fix();
  }
  
  // multi-digit right shift
  DecBigInt & rdshift(int const &ds) {
    if(ds < 0) return ldshift(-ds);
    if(uint(ds) >= digits()) return clear();
    v.erase(v.begin(), v.begin() + ds);
    return self;
  }
  
  // multi-digit left shift
  DecBigInt & ldshift(int const &ds) {
    if(ds < 0) return rdshift(-ds);
    v.insert(v.begin(), ds, 0);
    return self;
  }
  
  // add absolute value at offset
  DecBigInt & add_abs_at(DecBigInt const &a, uint const &off = 0) {
    if(&a == this) return add_abs_at(+a, off);
    uint1d_t t = 0;
    uint sd = digits(), ad = a.digits() + off;
    if(sd < ad) { v.resize(ad, 0); sd = ad; }
    uint i = off;
    for(; i < ad; ++i) v[i] = digit_fix(t = (t >= RADIX) + v[i] + a.v[i - off]);
    for(; i < sd; ++i) v[i] = digit_fix(t = (t >= RADIX) + v[i]);
    if(t >= RADIX) v.push_back(1);
    return self;
  }
  
  // multiply times digit
  DecBigInt & operator*=(uint1d_t const &rhs) {
    if(rhs == 0) return clear();
    uint2d_t t = 0;
    uint2d_t mul = rhs;
    uint sd = digits();
    uint i = 0;
    for(; i < sd; ++i) v[i] = (t = (t / RADIX) + v[i] * mul) % RADIX;
    t /= RADIX; if(t) v.push_back(t);
    return self;
  }
  DecBigInt operator*(uint1d_t const &rhs) const { return ((+self) *= rhs); }
  
  // multiplication
  DecBigInt operator*(DecBigInt const &rhs) const {
    if(not rhs) return DecBigInt();
    DecBigInt ret;
    uint sd = digits(), rd = rhs.digits(), dd = std::min(sd, rd);
    if(dd > MIN_KARTASUBA_DIGITS) {
      // Kartasuba algorithm
      uint hd = dd / 2;
      DecBigInt sh(self); sh.n = false; sh.rdshift(hd);
      DecBigInt sl(self); sl.n = false; sl.rdkeep (hd);
      DecBigInt rh(rhs);  rh.n = false; rh.rdshift(hd);
      DecBigInt rl(rhs);  rl.n = false; rl.rdkeep (hd);
      DecBigInt kh(sh * rh);
      DecBigInt kl(sl * rl);
      sl += sh;
      rl += rh;
      DecBigInt km(sl * rl); km -= kh; km -= kl;
      kh.ldshift(hd * 2);
      km.ldshift(hd);
      ret = kh + km + kl;
    } else {
      for(uint i = 0; i < sd; ++i) ret.add_abs_at(rhs * v[i], i);
    }
    ret.n = n xor rhs.n;
    return ret;
  }
  
  // in-place multiplication
  DecBigInt & operator*=(DecBigInt const &rhs) { return (self = self * rhs); }
  
  // power exponentiation
  DecBigInt & pow(uint const &exp) {
    if(exp == 0) return (self = 1);
    DecBigInt mul(self);
    for(uint e = exp - 1; e; e >>= 1) {
      if(e & 1) self *= mul;
      mul *= mul;
    }
    return self;
  }
  
  // modulo by small divisor
  int2d_t operator%(uint1d_t const &rhs) const {
    uint2d_t mul = RADIX % rhs;
    uint2d_t rem = 0;
    for(uint i = digits(); i--;) rem = (rem * mul + v[i]) % rhs;
    return (n ? -rem : rem);
  }
  
  // simplified in-place division by 2
  DecBigInt & div2() {
    static uint const c = RADIX / 2;
    int sd = digits();
    for(int i = 0; i < sd - 1; ++i) v[i] = (v[i] / 2) + (v[i + 1] & 1) * c;
    if(sd) v[sd - 1] /= 2;
    return fix();
  }
  
  // division algorithm
  DecBigInt & inplace_modulo(DecBigInt const &div, DecBigInt &quo) {
    if(not div) raise(SIGFPE);
    bool sn = n; n = false;
    DecBigInt d(div); d.n = false;
    quo.clear();
    DecBigInt m(1);
    int b = (digits() - d.digits() + 1) * RADIX_BITS;
    if(b > 0) {
      DecBigInt h(2); h.pow(b);
      for(d *= h, m = h; self and b >= 0; d.div2(), m.div2(), --b) {
        if(cmp_abs(d) >= 0) {
          sub_abs(d);
          quo.add_abs(m);
        }
      }
    }
    quo.n = div.n xor sn;
    n = sn;
    return self;
  }
  
  // modulo only (slightly faster)
  DecBigInt & inplace_modulo(DecBigInt const &div) {
    if(not div) raise(SIGFPE);
    bool sn = n; n = false;
    DecBigInt d(div); d.n = false;
    int b = (digits() - d.digits() + 1) * RADIX_BITS;
    if(b > 0) {
      DecBigInt h(2); h.pow(b);
      for(d *= h; self and b >= 0; d.div2(), --b) {
        if(cmp_abs(d) >= 0) sub_abs(d);
      }
    }
    n = sn;
    return self;
  }
  
  // division + modulo API
  std::pair<DecBigInt, DecBigInt> divmod(DecBigInt const &rhs) {
    std::pair<DecBigInt, DecBigInt> ret;
    ret.second = self;
    ret.second.inplace_modulo(rhs, ret.first);
    return ret;
  }
  
  // division and modulo operators
  DecBigInt & operator%=(DecBigInt const &rhs) { return inplace_modulo(rhs); }
  DecBigInt   operator% (DecBigInt const &rhs) const { return ((+self) %= rhs); }
  DecBigInt   operator/ (DecBigInt const &rhs) const { DecBigInt quo; (+self).inplace_modulo(rhs, quo); return quo; }
  DecBigInt & operator/=(DecBigInt const &rhs) { return (self = self / rhs); }
  
  // print to ostream
  friend std::ostream& operator<<(std::ostream& os, DecBigInt const &rhs) {
    if(not rhs) return os << '0';
    if(rhs.n) os << '-';
    os << rhs.v.back();
    for(uint i = rhs.digits() - 1; i--;) os << std::setw(RADIX_DEC_DIGITS) << std::setfill('0') << rhs.v[i];
    return os;
  }
  
  // read from istream
  friend std::istream& operator>>(std::istream& is, DecBigInt &rhs) {
    std::string word;
    is >> word;
    rhs.clear();
    if(word.empty()) return is;
    int l = 0;
    if(word[0] == '-') { l = 1; rhs.n = true; }
    for(int i = word.length() - 1; i >= l;) {
      uint1d_t t = 0, mul = 1;
      while(i >= l and mul < RADIX) { t += mul * (word[i--] - '0'); mul *= 10; }
      rhs.v.push_back(t);
    }
    rhs.fix();
    return is;
  }
  
  DecBigInt & cut(uint const &c=3) { if(v.size() > c) { v.resize(c); v.back() = 1; } return fix(); }
  
  uint64_t val() const {
    if(not self) return 0;
    uint64_t ret = v[0];
    if(v.size() > 1) ret += RADIX * uint64_t(v[1]);
    if(v.size() > 2) ret += RADIX * uint64_t(RADIX);
    return ret;
  }
};


uint64_t fib(uint64_t n) {
  DecBigInt FA = 0, FB = 1, FC = 1;
  DecBigInt MA = 0, MB = 1, MC = 1;
  DecBigInt TA, TB, TC;
  
  while(n) {
    if(n & 1) {
        TA = FA; TB = FB; TC = FC;
        FA = (TA * MA + TB * MB).cut();
        FB = (TB * MA + TC * MB).cut();
        FC = (TB * MB + TC * MC).cut();
    }
    
    TA = MA; TB = MB; TC = MC;
    MA = (TA * TA + TB * TB).cut();
    MB = (TB * TA + TC * TB).cut();
    MC = (TB * TB + TC * TC).cut();
    
    n >>= 1;
  }
  
  return FA.val();
}


DecBigInt fib2(uint64_t n) {
  DecBigInt FA = 0, FB = 1, FC = 1;
  DecBigInt MA = 0, MB = 1, MC = 1;
  DecBigInt TA, TB, TC;
  
  while(n) {
    if(n & 1) {
        TA = FA; TB = FB; TC = FC;
        FA = (TA * MA + TB * MB).cut(13);
        FB = (TB * MA + TC * MB).cut(13);
        FC = (TB * MB + TC * MC).cut(13);
    }
    
    TA = MA; TB = MB; TC = MC;
    MA = (TA * TA + TB * TB).cut(13);
    MB = (TB * TA + TC * TB).cut(13);
    MC = (TB * TB + TC * TC).cut(13);
    
    n >>= 1;
  }
  
  return FA;
}


int main() {
  ios_base::sync_with_stdio(false);
  cin.tie(NULL);
  
  string cStr;
  cin >> cStr;
  
  uint64_t c;
  istringstream ss(cStr); ss >> c;
  
  if(c == 0 and cStr.length() == 1) {
    cout << "0\n";
    return 0;
  }
  
  uint64_t mul = 1;
  for(uint i = 0; i < cStr.length(); ++i) mul = 10 * mul;
  
  uint64_t minF = (cStr[0] == '0' ? mul : 0);
  
  uint64_t F[94] = {0, 1};
  for(int i = 2; i < 94; ++i) F[i] = F[i-1] + F[i-2];
  
  for(int i = 0; i < 94; ++i) {
    if(F[i] >= minF and F[i] % mul == c) {
      cout << i << '\n';
      return 0;
    }
  }
  
  vector<uint64_t> pisano;
  pisano.push_back(1);
  pisano.push_back(60);
  pisano.push_back(300);
  pisano.push_back(1500);
  for(int i = 4; i <= 18; ++i) pisano.push_back(pisano.back() * 10);
  
  uint64_t tmul = 10;
  uint digit = 1;
  
  vector<uint64_t> positions;
  for(uint64_t i = 0; i < pisano[1]; ++i) {
    if(fib(i) % tmul == c % tmul) positions.push_back(i);
  }
  
  while(++digit <= cStr.length()) {
    tmul *= 10;
    
    vector<uint64_t> newPositions;
    
    uint64_t jmp = pisano[digit-1];
    
    for(uint64_t sft = 0; sft < pisano[digit]; sft += jmp) {
      for(uint j = 0; j < positions.size(); ++j) {
        uint64_t i = positions[j] + sft;
        if(fib(i) % tmul == c % tmul) newPositions.push_back(i);
      }
    }
    
    positions.swap(newPositions);
    
    if(positions.empty()) {
      cout << "NIE\n";
      return 0;
    }
  }
  --digit;
  
  DecBigInt dMinF(minF);
  
  uint64_t sft = 0;
  while(true) {
    for(uint j = 0; j < positions.size(); ++j) {
      DecBigInt candidate = fib2(positions[j] + sft);
      
      if(candidate > dMinF) {
        cout << positions[j] + sft << '\n';
        return 0;
      }
    }
    
    sft += pisano[digit];
  }
  
  return 0;
}